KR101964791B1 - Apparatus for generating hypochlorous acid - Google Patents

Abstract

The present invention relates to hypochlorous acid generating equipment and, especially, to hypochlorous acid generating equipment capable of producing hypochlorous acid by electrolyzing chlorine water and water, respectively. The hypochlorous acid generating equipment comprises: an external housing having a first accommodating unit which is formed with a synthetic resin material and filled with water inside, an inlet through which water flows to the first accommodating unit, and an outlet in which water inside the first accommodating unit flows to the outside; a first electrolytic unit arranged inside the external housing and electrolyzing chlorine water supplied from the outside; and a second electrolytic unit electrolyzing water filled in the external housing. Chlorine gas generated when the chlorine water is electrolyzed in the first electrolytic unit moves to the first accommodating unit; and hypochlorous acid (HOCL) is generated when the water filled in the first accommodating unit is combined with the chloride gas while being electrolyzed. The present invention is able to easily and efficiently generate hypochlorous acid (HOCL).

Description

{APPARATUS FOR GENERATING HYPOCHLOROUS ACID}

The present invention relates to an apparatus for producing hypochlorous acid, and more particularly, to a hypochlorous acid producing apparatus capable of producing hypochlorous acid by electrolyzing chlorine water and water, respectively.

 In general, in a place where sterilization and hygiene treatment are required such as various food materials such as vegetables, tableware, kitchen utensils, etc., it is necessary to disinfect the object to be cleaned conveniently so that proper disinfection and sanitation can be achieved.

Conventionally, sterilization methods include a method of cleaning objects to be cleaned with chemicals, and a method of sterilizing by ozone. However, these methods are often impossible to use due to various conditions of use.

Particularly, when ozone is used, there arises a problem of hazard due to residual ozone.

In addition, the disinfection method using chemicals is costly, causes post-use drug residue problems and harmful problems, and because of these problems, thorough disinfection and hygiene must be performed in places such as restaurants and large foodservice stations However, the conventional disinfection method has many problems, so it causes the disinfecting and hygienic management to be neglected, thereby often causing a group food poisoning accident.

In recent years, there are many cases where disinfection, washing and sterilization are performed using hypochlorous acid (HOCL).

However, the conventional device for producing hypochlorous acid (HYPOCHLOROUS ACID, HOCL) has a complicated structure and has a limitation in generating hypochlorous acid (HOCL) efficiently.

Registration Utility Model 20-0441233 Patent Document 10-2011-0109398 Patent Document No. 10-2011-0117401

It is an object of the present invention to provide a hypochlorous acid generation apparatus capable of efficiently and easily producing hypochlorous acid (HOCL) without complicating the structure.

In order to attain the above object, the hypochlorous acid generating apparatus of the present invention comprises a first accommodating portion formed of a synthetic resin material for filling water therein, an inlet for introducing water into the first accommodating portion, An outer housing having an outlet through which water is discharged to the outside; A first electrolytic unit disposed inside the outer housing for electrolyzing chlorine water supplied from the outside; And chlorine gas generated by electrolyzing the chlorine water in the first electrolytic part moves to the first accommodating part, and the chlorine gas generated in the first electrolytic part moves to the first accommodating part, (HOCL) is generated by combining with the chlorine gas while electrolyzing the water filled in the first accommodating portion.

An electrolytic housing disposed inside the outer housing, the electrolytic housing having a second receiving portion filled with chlorine water from the outside and filled therein; A positive electrode disposed inside the electrolytic housing and having positive electrodes connected thereto; A negative electrode plate spaced apart from the positive electrode plate in the electrolytic housing and having a negative electrode connected thereto; And a valve installed in the electrolytic housing, wherein chlorine gas generated by electrolysis of chlorine water in the second containing portion is discharged to the first containing portion through the valve, and water in the first containing portion It is electrolyzed and mixed with chlorine gas to produce hypochlorous acid (HOCL).

The valve is mounted on top of the electrolytic housing, and the outlet is located above the valve.

The valve is opened only when chlorine gas is discharged from the inside of the electrolytic housing to the outside.

A guide plate is mounted on the inside of the electrolytic housing. The guide plate is formed with a guide hole through which the positive electrode plate and the negative electrode plate pass, and a plurality of through holes are formed in the up and down direction.

The guide plate includes: a first guide plate disposed at a lower portion; And a second guide plate located above the first guide plate, wherein the through-holes formed in the second guide plate are smaller in diameter than the through-holes formed in the first guide plate and have a larger number .

The electrolytic housing comprises: an upper case made of a metal and having an open bottom; A lower case which is made of metal and has an open upper portion and is disposed apart from the lower portion of the upper case; And a connection case having a hollow shape and disposed between the upper case and the lower case to connect the upper case and the lower case.

The positive electrode is electrically connected to the upper case, the negative electrode is electrically connected to the lower case, and the second electrolysis unit is composed of an upper case electrically connected to the positive electrode and a lower case electrically connected to the negative electrode.

According to the hypochlorous acid generating apparatus of the present invention as described above, hypochlorous acid (HOCL) can be efficiently and easily produced by electrolyzing the chlorine water and water separately without complicating the overall structure of the apparatus.

The produced hypochlorous acid can be used as a cleaning agent, a disinfectant, a disinfectant, and the like.

1 is a perspective view of a generation apparatus according to an embodiment of the present invention,
2 is an exploded perspective view of a production apparatus according to an embodiment of the present invention,
3 is an exploded perspective view of an electrolytic cell according to an embodiment of the present invention,
FIG. 4 is a sectional view taken along line AA of FIG. 1,
Fig. 5 is a sectional view taken along the line BB in Fig. 1,
6 is a cross-sectional view illustrating a state in which HOCL is generated by a generating apparatus according to an embodiment of the present invention;

As shown in FIGS. 1 to 5, the apparatus for producing hypochlorous acid according to the present invention comprises an outer housing 10, a first electrolytic unit, and a second electrolytic unit.

The outer housing 10 is made of a synthetic resin material and has a first receiving portion 11 filled with water.

The outer housing 10 has an inlet 12 through which water flows into the first receiving portion 11 and an outlet 13 through which water in the first receiving portion 11 is discharged to the outside Respectively.

The first electrolytic unit is disposed inside the outer housing 10 and electrolyzes chlorine water supplied from the outside.

The first electrolytic unit electrolyzes the chlorine water supplied from the outside to generate chlorine gas.

The second electrolytic part electrolyzes the water filled in the outer housing (10).

The chlorine gas generated in the first electrolytic unit moves to the first accommodating unit 11 of the outer housing 10 and the water filled in the first accommodating unit 11 is sucked by the second electrolytic unit And is combined with the chlorine gas to generate hypochlorous acid (HOCL, HYPOCHLOROUS ACID).

The generated hypochlorous acid is discharged to the outside through the outlet 13 of the outer housing 10.

The first electrolytic unit includes an electrolytic housing 20, a positive electrode plate 30, a negative electrode plate 40, and a valve 50.

The electrolytic housing 20 has a cylindrical shape and is disposed inside the outer housing 10. A second accommodating portion 21 is formed inside the electrolytic housing 20 to supply and fill the chlorine water from the outside, have.

The positive electrode plate 30 is disposed inside the electrolytic housing 20 and the positive electrode 35 is connected from the outside.

The negative electrode plate 40 is disposed in the electrolytic housing 20 so as to be spaced apart from the positive electrode plate 30 and the negative electrode 45 is connected to the negative electrode plate 40 from the outside.

At this time, the positive electrode 35 and the negative electrode 45 are preferably made of titanium.

In the present embodiment, the positive electrode plate 30 and the negative electrode plate 40 are formed of a plurality of the positive electrode plates 30 and the negative electrode plate 40, respectively.

The valve 50 is installed in the electrolytic housing 20 to discharge chlorine gas generated in the electrolytic housing 20 to the outside.

The valve (50) is opened only when chlorine gas is discharged from the inside of the electrolytic housing (20) to the outside.

The valve 50 is mounted on the upper portion of the electrolytic housing 20 and the outlet 13 formed in the outer housing 10 is positioned above the valve 50.

Thus, the chlorine gas generated in the electrolytic housing 20 can be easily discharged upwardly through the valve 50, mixed with water and discharged to the outside through the outlet 13 do.

The chlorine gas generated by electrolyzing the chlorine water in the second accommodating portion 21 by the above-mentioned first electrolytic portion and second dissolving portion is supplied to the first accommodating portion 11 through the valve 50 And the water is electrolyzed in the first accommodating part 11 and mixed with chlorine gas to generate hypochlorous acid (HOCL).

A guide plate (25) is mounted inside the electrolytic housing (20).

The guide plate 25 is formed with guide holes 26a and 26b through which the positive electrode plate 30 and the negative electrode plate 40 penetrate in the vertical direction and the guide plates 25 are provided with guide holes 26a and 26b And a plurality of through holes 26b and 27b are formed in the up and down direction.

The guide plate 25 allows the cathode plate 30 and the cathode plate 40 to be disposed at a fixed position without flowing, and the through holes 26b and 27b are formed so that the electrolyzed chlorine gas moves upward and downward .

The number of the guide plates 25 may be one, but it is preferable that the number of the guide plates 25 is plural.

In this embodiment, the guide plate 25 includes a first guide plate 26 and a second guide plate 27.

The first guide plate 26 is located at the lower portion and the second guide plate 27 is located at the upper portion.

Guide holes 26a and 26b for inserting the positive electrode plate 30 and the negative electrode plate 40 are formed in the first guide plate 26 and the second guide plate 27. The through holes 26b, 27b).

At this time, the through holes 27b formed in the upper second guide plate 27 are smaller in diameter and larger in number than the through holes 26b formed in the first guide plate 26.

By mounting a plurality of guide plates 25 inside the electrolytic housing 20 as described above, electrolysis can be performed several times within the electrolytic housing 20, so that electrolysis of chlorine water can be performed more easily .

That is, in the embodiment of the present embodiment, since two guide plates 25 are provided, three electrolytic chambers are formed in the electrolytic housing 20, and the electrolytic electrolysis is performed in total three stages.

Since the through hole 26b of the first guide plate 26 disposed at the lower portion is large and the through hole 27b of the second guide plate 27 disposed at the upper portion is small, The electrolysis is performed in one space without being performed in one space, and then the electrolysis is continued to the other space after being electrolyzed in one space, so that electrolysis can be repeatedly performed almost uniformly in three spaces.

That is, the electrolytic solution is primarily electrolyzed in the space existing in the lower portion of the first guide plate 26, the remaining one is raised through the through hole 26b formed in the first guide plate 26, The space between the guide plate 26 and the second guide plate 27 is secondarily electrolyzed in the space and the rest is raised again through the through hole 27b formed in the second guide plate 27, The second guide plate 27, and the second guide plate 27, respectively.

By performing the electrolysis several times as described above, the electrolysis of the chlorine water can be performed more efficiently.

The second electrolytic part may be formed by mounting a separate positive electrode and negative electrode to the first accommodating part 11.

However, in the present embodiment, the second electrolytic portion uses the electrolytic housing 20.

To this end, the electrolytic housing 20 includes an upper case 22, a lower case 23, and a connection case 24.

The upper case 22 is made of metal and the bottom is opened.

The lower case 23 is made of metal and has an open upper portion and is disposed apart from the lower portion of the upper case 22.

The upper case 22 and the lower case 23 are preferably made of titanium.

The connection case 24 is made of an insulating material and has a hollow shape and is disposed between the upper case 22 and the lower case 23 to connect the upper case 22 to the lower case 23.
The tubular electrolytic housing 20 having the second accommodating portion 21 therein is formed by the engagement of the upper case 22, the connection case 24 and the lower case 23.

The upper case 22 and the lower case 23 are not electrically connected by the connection case 24.

The positive electrode (35) connected to the positive electrode plate (30) is electrically connected to the upper case (22).

The negative electrode 45 connected to the negative electrode plate 40 is electrically connected to the lower case 23.

Therefore, the upper case 22 becomes an anode in the outer housing 10, the lower case 23 becomes a cathode in the inside of the outer housing 10, An upper case 22 electrically connected to the negative electrode 35 and a lower case 23 electrically connected to the negative electrode 45.

When electricity is applied to the positive electrode 35 and the negative electrode 45 in a state where water is supplied to the first accommodating portion 11 and chlorine is supplied to the second accommodating portion 21 by the above configuration , The chlorine water filled in the second accommodating portion (21) is electrolyzed to generate chlorine gas.

The chlorine gas thus generated is discharged to the outside of the electrolytic housing 20 through the valve 50, that is, the first accommodating portion 11.

The chlorine gas discharged into the first accommodating portion 11 is electrolyzed by the upper case 22 and the lower case 23 together with the water filled in the chlorine gas to generate hypochlorous acid, The generated hypochlorous acid is discharged to the outside through the outlet (13) formed in the outer housing (10).

As described above, the present invention can easily produce hypochlorous acid by electrolyzing chlorine water and electrolyzing water separately.

The apparatus for producing hypochlorous acid according to the present invention is not limited to the above-described embodiments, and can be variously modified within the scope of the technical idea of the present invention.

10: outer housing, 11: first receiving portion, 12: inlet, 13: outlet,
The present invention relates to an electrolytic device for electrolytic electrolysis in which electrolytic electrolytic electrolysis is carried out by electrolytic electrolysis using electrolytic electrolytic electrolysis. : Second guide plate, 27a: guide ball, 27b: through hole,
30: positive electrode plate, 35: positive electrode
40: cathode plate, 45: negative electrode,
50: Valve.

Claims (8)

delete An outer housing having a first housing portion made of a synthetic resin material and filled with water and having an inlet through which water is introduced into the first housing portion and an outlet through which water in the first housing portion is discharged to the outside; A first electrolytic unit disposed inside the outer housing for electrolyzing chlorine water supplied from the outside; And a second electrolytic unit for electrolyzing the water filled in the outer housing,
Wherein the first electrolytic unit comprises:
An electrolytic housing having a cylindrical shape and disposed inside the outer housing, the electrolytic housing having a second receiving portion filled with chlorine water supplied from the outside to the inside; A positive electrode disposed inside the electrolytic housing and having positive electrodes connected thereto; A negative electrode plate spaced apart from the positive electrode plate in the electrolytic housing and having a negative electrode connected thereto; And a valve mounted on the electrolytic housing,
Wherein the electrolytic housing comprises:
An upper case made of metal and opened at a lower portion thereof; A lower case which is made of metal and has an open upper portion and is disposed apart from the lower portion of the upper case; And a connection case made of a hollow material and disposed between the upper case and the lower case to connect the upper case and the lower case to each other,
Wherein the tubular electrolytic housing having the second accommodating portion therein is formed by engagement of the upper case, the connection case, and the lower case,
A positive electrode connected to the positive electrode plate is electrically connected to the upper case, a negative electrode connected to the negative electrode plate is electrically connected to the lower case,
The second electrolytic unit is composed of an upper case electrically connected to the positive electrode and a lower case electrically connected to the negative electrode while being disposed inside the outer housing,
The chlorine water is electrolyzed by the cathode plate connected to the anode and the cathode plate connected to the cathode and the cathode, and the lower case is electrolyzed to generate chlorine gas.
The generated chlorine gas is discharged from the electrolytic housing to the first accommodating portion through the valve. Water charged in the first accommodating portion is electrolyzed by the upper case connected to the positive electrode and the lower case connected to the negative electrode, To produce hypochlorous acid (HOCL). The method of claim 2,
The valve being mounted on an upper portion of the electrolytic housing,
Wherein the outlet is located above the valve. The method of claim 3,
Wherein the valve is opened only when chlorine gas is discharged from the inside of the electrolytic housing to the outside. The method of claim 2,
A guide plate is mounted inside the electrolytic housing,
A guide hole through which the positive electrode plate and the negative electrode plate are passed is formed in the guide plate,
Wherein a plurality of through-holes are formed in a vertical direction. The method of claim 5,
The guide plate
A first guide plate located at a lower portion;
And a second guide plate positioned above the first guide plate,
Wherein the through-holes formed in the second guide plate are smaller in diameter and larger in number than the through-holes formed in the first guide plate. delete delete

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